Authors: Liangliang Tang, Chang Xu, Xingying Chen

Abstract:

GaInAsSb cells probably show better performance than GaSb cells in low-temperature thermophotovoltaic systems due to lower bandgap; however, few experiments proved this phenomenon so far. In this paper, numerical simulation is used to evaluate GaInAsSb and GaSb cells with similar structures under different radiation temperatures. We found that GaInAsSb cells with n-type emitters show slightly higher output power densities compared with that of GaSb cells with n-type emitters below 1,550 K-blackbody radiation, and the power density of the later cells will suppress the formers above this temperature point. During the temperature range of 1,000~2,000 K, the efficiencies of GaSb cells are about twice of GaInAsSb cells if perfect filters are used to prevent the emission of the non-absorbed long wavelength photons. Several parameters that affect the GaInAsSb cell were analyzed, such as doping profiles, thicknesses of GaInAsSb epitaxial layer and surface recombination velocity. The non-p junctions, i.e., n-type emitters are better for GaInAsSb cell fabrication, which is similar to that of GaSb cells.

Keywords: Thermophotovoltaic cell, GaSb, GaInAsSb, diffused emitters.

Digital Object Identifier (DOI): doi.org/10.5281/zenodo.1126712

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References:

[1] L.M. Fraas, G.R. Girard, J.E. Avery, B.A. Arau, V.S. Sundaram, A.G. Thompson, J.M. Gee, Gasb Booster Cells for over 30-Percent Efficient Solar-Cell Stacks, J Appl Phys, 66 (1989) 3866-3870.
[2] C. Wang, H. Choi, S. Ransom, G. Charache, L. Danielson, D. DePoy, High-quantum-efficiency 0.5 eV GaInAsSb/GaSb thermophotovoltaic devices, Applied physics letters, 75 (1999) 1305-1307.
[3] H. Choi, C. Wang, G. Turner, M. Manfra, D. Spears, G. Charache, L. Danielson, D. Depoy, High-performance GaInAsSb thermophotovoltaic devices with an AlGaAsSb window, Applied physics letters, 71 (1997) 3758-3760.
[4] R. Magri, A. Zunger, H. Kroemer, Evolution of the band-gap and band-edge energies of the lattice-matched GaInAsSb∕ GaSb and GaInAsSb∕ InAs alloys as a function of composition, Journal of applied physics, 98 (2005) 043701.
[5] M.W. Dashiell, J.F. Beausang, H. Ehsani, G. Nichols, D.M. Depoy, L.R. Danielson, P. Talamo, K.D. Rahner, E.J. Brown, S.R. Burger, Quaternary InGaAsSb thermophotovoltaic diodes, Electron Devices, IEEE Transactions on, 53 (2006) 2879-2891.
[6] L.M. Fraas, J.E. Avery, H.X. Huang, Thermophotovoltaic furnace-generator for the home using low bandgap GaSb cells, Semicond Sci Tech, 18 (2003) S247-S253.
[7] A.W. Bett, O.V. Sulima, GaSb photovoltaic cells for applications in TPV generators, Semicond Sci Tech, 18 (2003) S184-S190.
[8] K. Qiu, A. Hayden, Direct thermal to electrical energy conversion using very low bandgap TPV cells in a gas-fired furnace system, Energy Conversion and Management, 79 (2014) 54-58.
[9] W.R. Chan, P. Bermel, R.C. Pilawa-Podgurski, C.H. Marton, K.F. Jensen, J.J. Senkevich, J.D. Joannopoulos, M. Soljačić, I. Celanovic, Toward high-energy-density, high-efficiency, and moderate-temperature chip-scale thermophotovoltaics, Proceedings of the National Academy of Sciences, 110 (2013) 5309-5314.
[10] K. Qiu, A. Hayden, M. Mauk, O. Sulima, Generation of electricity using InGaAsSb and GaSb TPV cells in combustion-driven radiant sources, Solar energy materials and solar cells, 90 (2006) 68-81.
[11] L.M. Fraas, J.E. Avery, G. Girard, G.R. Girard, Tandem Photovoltaic Solar Cell with III-V Diffused Junction Booster Cell, in, Boeing Co (Boei), US patent,1992.
[12] L.M. Fraas, V.S. Sundaram, J.E. Avery, P.E. Gruenhaum, E. Malocsay, III-V Solar Cells and Doping Progresses, in, Boeing Co (Boei), US patent 1993.
[13] L. Tang, L.M. Fraas, Z. Liu, C. Xu, X. Chen, Performance Improvement of the GaSb Thermophotovoltaic Cells with n-Type Emitters, IEEE transactions on electron devices, 62 (2015) 2809-2815.
[14] X. Peng, X. Guo, B. Zhang, X. Li, X. Zhao, X. Dong, W. Zheng, G. Du, Numerical analysis of the short-circuit current density in GaInAsSb thermophotovoltaic diodes, Infrared Physics & Technology, 52 (2009) 152-157.
[15] O. Sulima, R. Beckert, A. Bett, J. Cox, M. Mauk, InGaAsSb photovoltaic cells with enhanced open-circuit voltage, IEE Proceedings-Optoelectronics, 147 (2000) 199-204.
[16] O.V. Sulima, A.W. Bett, M.G. Mauk, B.Y. Ber, P.S. Dutta, Diffusion of Zn in TPV materials: GaSb, InGaSb, InGaAsSb and InAsSbP. In: Thermophotovoltaic Generation of Electricity, in: Thermophotovoltaic Generation of Electricity: Fifth Conference on Thermophotovoltaic Generation of Electricity, 2003, pp. 402-413.
[17] H. Ye, L. Tang, K. Li, The intrinsic relationship between the kink-and-tail and box-shaped zinc diffusion profiles in n-GaSb, Semiconductor Science and Technology, 28 (2013) 015001.
[18] H. Ye, L. Tang, Q. Ni, Identification of the dissociative and kick-out diffusion mechanisms of Zn diffusion in GaAs by photoluminescence analysis, Materials Science & Engineering B, 197 (2015) 1-4.
[19] Y. Wang, N. Chen, X. Zhang, T. Huang, Z. Yin, Y. Wang, H. Zhang, Evaluation of thermal radiation dependent performance of GaSb thermophotovoltaic cell based on an analytical absorption coefficient model, Solar Energy Materials and Solar Cells, 94 (2010) 1704-1710.
[20] D.A. Clugston, P.A. Basore, PC1D version 5: 32-bit solar cell modeling on personal computers, in: Photovoltaic Specialists Conference, 1997., Conference Record of the Twenty-Sixth IEEE, IEEE, 1997, pp. 207-210.